Until now. Scientists at The Scripps Research Institute (TSRI) have announced the development of the first stable semisynthetic organism. Building on their 2014 study in which they synthesized a DNA base pair, the researchers created a new bacterium that uses the four natural bases (called A, T, C and G), which every living organism possesses, but that also holds as a pair two synthetic bases called X and Y in its genetic code.
TSRI Professor Floyd Romesberg and his colleagues have now shown that their
«We’ve made this semisynthetic organism more
While applications for this kind of organism are still far in the future, the researchers say the work could be used to create new functions for
Building a Unique Organism
When Romesberg and his colleagues announced the development of X and Y in 2014, they also showed that modified E. coli bacteria could hold this synthetic base pair in their genetic code. What these E. coli couldn’t do, however, was keep the base pair in their code indefinitely as they divided. The X and Y base pair was dropped over time, limiting the ways the organism could use the additional information possessed in their DNA.
«Your genome isn’t just stable for a day," said Romesberg. «Your genome has to be stable for the scale of your lifetime. If the semisynthetic organism is going to really be an organism, it has to be able to stably maintain that information.»
Romesberg compared this flawed organism to an infant. It had some learning to do before it was ready for real life.
In stepped TSRI Graduate Student Yorke Zhang and Brian Lamb, an American Cancer Society postdoctoral fellow in the Romesberg lab at the time of the study. Together, they helped develop the means for the
First, Zhang and Lamb,
Next, the researchers optimized their previous version of Y. The new Y was a chemically different molecule that could be better recognized by the enzymes that synthesize DNA molecules during DNA replication. This made it easier for cells to copy the synthetic base pair.
A New Use for CRISPR-Cas9
Finally, the researchers set up a «spell check» system for the organism using
The genetic tools in
Knowing this, the researchers designed their organism to see a genetic sequence without X and Y as a foreign invader. A cell that dropped X and Y would be marked for destruction, leaving the scientists with an organism that could hold on to the new bases. It was like the organism was immune to unnatural base pair loss.
«We were able to address the problem at a fundamental level," said Lamb, who now serves as a research scientist at Vertex Pharmaceuticals.
Their semisynthetic organism was thus able to keep X and Y in its genome after dividing 60 times, leading the researchers to believe it can hold on to the base pair indefinitely.
«We can now get the light of life to stay on," said Romesberg. «That suggests that all of life’s processes can be subject to manipulation.»
A Foundation for Future Research
Romesberg emphasized that this work is only in single cells and is not meant to be used in more complex organisms. He added that the actual applications for this semisynthetic organism are «zero» at this point. So far, scientists can only get the organism to store genetic information.
Next, the researchers plan to study how their new genetic code can be transcribed into RNA, the molecule in cells needed to translate DNA into proteins. «This study lays the foundation for what we want to do going forward," said Zhang.
Additional authors of the study, «A semisynthetic organism engineered for the stable expansion of the genetic alphabet," were Aaron W. Feldman and Anne Xiaozhou Zhou of TSRI; Thomas Lavergne of the University of Grenoble; and Lingjun Li of Henan Normal University.
The study was supported by the National Institutes of Health (grant GM060005), a National Science Foundation Graduate Research Fellowship (grant
Source: http://www.scripps.edu/news/press/2017/20170123romesberg.html
